Elizabeth M. Black scite author profile

Elizabeth M. Black

3Publications

75Citation Statements Received

303Citation Statements Given

How they've been cited

How they cite others

209

297

Affiliations

Yale Cancer Center, Yale University, Rockefeller University

Publications

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Repetitive Fragile Sites: Centromere Satellite DNA as a Source of Genome Instability in Human Diseases

Black

Giunta

2018

Genes

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Maintenance of an intact genome is essential for cellular and organismal homeostasis. The centromere is a specialized chromosomal locus required for faithful genome inheritance at each round of cell division. Human centromeres are composed of large tandem arrays of repetitive alpha-satellite DNA, which are often sites of aberrant rearrangements that may lead to chromosome fusions and genetic abnormalities. While the centromere has an essential role in chromosome segregation during mitosis, the long and repetitive nature of the highly identical repeats has greatly hindered in-depth genetic studies, and complete annotation of all human centromeres is still lacking. Here, we review our current understanding of human centromere genetics and epigenetics as well as recent investigations into the role of centromere DNA in disease, with a special focus on cancer, aging, and human immunodeficiency–centromeric instability–facial anomalies (ICF) syndrome. We also highlight the causes and consequences of genomic instability at these large repetitive arrays and describe the possible sources of centromere fragility. The novel connection between alpha-satellite DNA instability and human pathological conditions emphasizes the importance of obtaining a truly complete human genome assembly and accelerating our understanding of centromere repeats’ role in physiology and beyond.

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Keeping RelApse in Chk: molecular mechanisms of Chk1 inhibitor resistance in lymphoma

Black

Joo

Kabeche

2022

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Chk1 is a member of the DNA damage response pathway, whose loss leads to replication stress and genome instability. Because of its protective role against lethal levels of DNA replication stress, Chk1 has been studied as a valuable and intriguing target for cancer therapy. However, one of the most prominent challenges with this strategy is development of resistance to Chk1 inhibitors, rendering the treatment ineffective. In their recent papers, Hunter and colleagues demonstrate multiple mechanisms by which Chk1 inhibitor resistance can arise in lymphomas. Specifically, this series of papers identify the relationship between dysfunction in NF-κB and the development of Chk1 inhibitor resistance through a loss of Chk1 activity in mouse models of lymphoma. They identify that cells lacking Chk1 activity can compensate for this loss through up-regulation of alternative pathways, such as PI3K/AKT. Finally, this work also identifies a novel role for Claspin, an important Chk1 activator, in female fertility and cancer development, furthering our understanding of how dysfunction in the Claspin/Chk1 signaling pathway affects disease states. These findings improve our understanding of drug resistance in cancer therapy, which has important implications for clinical use of Chk1 inhibitors.

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ATR protects centromere identity by promoting DAXX association with PML nuclear bodies

Trier

Joo

Black

et al. 2022

Preprint

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Centromere protein A (CENP-A) defines centromere identity and nucleates kinetochore formation for mitotic chromosome segregation. Here, we show that Ataxia telangiectasia and Rad3-related (ATR) kinase, a master regulator of the DNA damage response, protects CENP-A occupancy at interphase centromeres in a DNA damage-independent manner. As ATR localizes to promyelocytic leukemia nuclear bodies (PML NBs) in unperturbed cells, we hypothesized that ATR protects CENP-A occupancy by regulating the localization of the histone H3.3 chaperone and PML NB component, DAXX. Indeed, we found that ATR inhibition reduces DAXX association with PML NBs, resulting in the DAXX-dependent loss of CENP-A from interphase centromeres. Lastly, we demonstrate that CENP-A occupancy is not restored until G1 of the following cell cycle, leading to increased mitotic chromosome segregation defects. These findings demonstrate a novel mechanism by which ATR protects centromere identity and genome stability.

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